Interferometric Constraints on Spacelike Coherent Rotational Fluctuations.

Precision measurements are reported of the cross-spectrum of rotationally induced differential position displacements in a pair of colocated 39 m long, high-power Michelson interferometers. One arm of each interferometer is bent 90° near its midpoint to obtain sensitivity to rotations about an axis normal to the plane of the instrument. The instrument achieves quantum-limited sensing of spatially correlated signals in a broad frequency band extending beyond the 3.9-MHz inverse light travel time of the apparatus. For stationary signals with bandwidth Δf>10  kHz, the sensitivity to rotation-induced strain h of classical or exotic origin surpasses CSD_{δh}<t_{P}/2, where t_{P}=5.39×10^{-44}  s is the Planck time. This measurement is used to constrain a semiclassical model of nonlocally coherent rotational degrees of freedom of spacetime, which have been conjectured to emerge in holographic quantum geometry but are not present in a classical metric.

[1]  V. Vedral,et al.  Non-Gaussianity as a Signature of a Quantum Theory of Gravity , 2020, 2004.01189.

[2]  K. Zurek,et al.  Observational signatures of quantum gravity in interferometers , 2019, Physics Letters B.

[3]  K. Dooley,et al.  An experiment for observing quantum gravity phenomena using twin table-top 3D interferometers , 2020, Classical and Quantum Gravity.

[4]  M. Bojowald,et al.  Physical Implications of a Fundamental Period of Time. , 2020, Physical review letters.

[5]  F. Wilczek,et al.  The noise of gravitons , 2020, 2005.07211.

[6]  C. Hogan Cosmological constant in coherent quantum gravity , 2020, 2003.14255.

[7]  T. Banks Holographic Space-Time and Quantum Information , 2020, Frontiers in Physics.

[8]  K. Zurek,et al.  Spacetime fluctuations in AdS/CFT , 2019, Journal of High Energy Physics.

[9]  S. Meyer,et al.  Symmetries of CMB Temperature Correlation at Large Angular Separations , 2019, The Astrophysical Journal.

[10]  C. Hogan Pattern of perturbations from a coherent quantum inflationary horizon , 2019, Classical and Quantum Gravity.

[11]  M. Zucco,et al.  Twin beam quantum-enhanced correlated interferometry for testing fundamental physics , 2018, Communications Physics.

[12]  H. Grote,et al.  Novel signatures of dark matter in laser-interferometric gravitational-wave detectors , 2019, Physical Review Research.

[13]  S. Giddings Black holes in the quantum universe , 2019, Philosophical Transactions of the Royal Society A.

[14]  C. Hogan Nonlocal entanglement and directional correlations of primordial perturbations on the inflationary horizon , 2018, Physical Review D.

[15]  T. Banks,et al.  Cosmological Implications of the Bekenstein Bound , 2018, Jacob Bekenstein.

[16]  Jacob M. Taylor,et al.  Tabletop experiments for quantum gravity: a user’s manual , 2018, Classical and Quantum Gravity.

[17]  Č. Brukner,et al.  Bell’s theorem for temporal order , 2017, Nature Communications.

[18]  T. Banks,et al.  Why The Cosmological Constant is a Boundary Condition , 2018, 1811.00130.

[19]  T. Banks,et al.  The holographic spacetime model of cosmology , 2018, International Journal of Modern Physics D.

[20]  G. Hooft Virtual Black Holes and Space–Time Structure , 2018 .

[21]  Rainer Weiss,et al.  Interferometric constraints on quantum geometrical shear noise correlations , 2017, 1703.08503.

[22]  L. Sonderhouse,et al.  A Fermi-degenerate three-dimensional optical lattice clock , 2017, Science.

[23]  Rainer Weiss,et al.  MHz gravitational wave constraints with decameter Michelson interferometers , 2016, 1611.05560.

[24]  S. Meyer,et al.  The Holometer: An Instrument to Probe Planckian Quantum Geometry , 2016, 1611.08265.

[25]  J. Richardson,et al.  Statistical model of exotic rotational correlations in emergent space-time , 2016, 1607.03048.

[26]  G. Hooft Black Hole Unitarity and Antipodal Entanglement , 2016, 1601.03447.

[27]  Rainer Weiss,et al.  First Measurements of High Frequency Cross-Spectra from a Pair of Large Michelson Interferometers. , 2015, Physical review letters.

[28]  T. Jacobson Entanglement Equilibrium and the Einstein Equation. , 2015, Physical review letters.

[29]  C. Hogan Exotic rotational correlations in quantum geometry , 2015, 1509.07997.

[30]  M Genovese,et al.  Quantum light in coupled interferometers for quantum gravity tests. , 2013, Physical review letters.

[31]  E. Black An introduction to Pound–Drever–Hall laser frequency stabilization , 2001 .

[32]  A. Nelson,et al.  Effective field theory, black holes, and the cosmological constant , 1998, hep-th/9803132.

[33]  Jacobson,et al.  Thermodynamics of spacetime: The Einstein equation of state. , 1995, Physical review letters.

[34]  Howard Georgi,et al.  Effective Field Theory , 1993 .

[35]  Steven Weinberg,et al.  The Cosmological Constant Problem , 1989 .

[36]  I. Antoniadis,et al.  On the cosmological constant problem , 1984 .

[37]  P. Welch The use of fast Fourier transform for the estimation of power spectra: A method based on time averaging over short, modified periodograms , 1967 .